Techniques for Personalized and Adaptive Search Services

ABSTRACT

Techniques are presented that include defining one or more personalized categories, wherein each personalized category comprises one or more terms, identifying one or more of said personalized categories that are associated with a user query, identifying one or more terms that are associated with said user query and with said personalized category, and adding said identified one or more terms to said user query.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional application of U.S. patent applicationSer. No. 12/169,306, filed Jul. 8, 2008, incorporated by referenceherein, which is a continuation of U.S. patent application Ser. No.10/155,697, filed May 24, 2002, also incorporated by reference herein.

FIELD OF THE INVENTION

This invention relates to searching for information over a computernetwork, and, more specifically, the invention relates to techniques forpersonalized and adaptive search services.

BACKGROUND OF THE INVENTION

Computer networks used for knowledge searching and retrieval are wellknown. For example, see U.S. Pat. No. 5,873,080 to Coden et al., issuedon Feb. 16, 1999; U.S. Pat. No. 5,875,446 to Brown et al., issued onFeb. 23, 1999; U.S. Pat. No. 5,913,208 to Brown et al., issued Jun. 15,1999; and U.S. Pat. No. 5,819,265 to Ravin et al., issued on Oct. 6,1998, the disclosures of which are hereby incorporated by reference. Inall of these patents, a primary purpose is to provide better methods toretrieve relevant documents in response to user queries.

In order to improve relevancy, information is categorized into groups ofsubjects. The categorization of the text documents is one of the mosteffective methods to help users organize information. In general, thecontent of the text document is analyzed to determine the words andphrases that contribute to the context of the document. The document isthen associated, based on the context and content, to one or morecategories of a given taxonomy. Once the document is associated with acategory of a taxonomy, the users can easily navigate within thetaxonomy of their interest to find relevant information. The “Yahoo!”search Web site is designed based on this concept of categorization.Each document is listed under one category or subcategory.

Once the information is categorized based on a taxonomy, the users cannarrow their search scope within a category or subcategory. This waythey can increase the relevance of the documents that they retrieved.Today, most search Web sites are based on this principle.

The context of the query in general is very important to be able toreturn the relevant results. As an example, if the word Java is usedwith the context of a coffee type, then this information must becommunicated to the search engine. Otherwise, the search engine wouldreturn results out of context such as references to a computer languageor a germ or a lyric. One way to associate a context to a query is tolook at a user profile. A user profile contains a set of categories or ataxonomy that identifies user interests. When the user forms a query, itcan be associated to one or more categories, which helps to determineand possibly expand the context of the query.

The amount of information published over the Internet grew so rapidlythat it became very difficult to find the information. In order to makethe searching of Internet content more practical, categorization of theWeb content was proposed. The unstructured Web content was categorizedby using specific taxonomies. Today, for many search engines, users areexpected to know and select the category for the information that theylook for. In general, the categories are organized in a tree structure.There are seven to 15 main categories, such as Art, Business, Computers,Education, Entertainment, and the other subcategories are organizedunder these main categories. In order to cover the information spaceproperly, seven to 15,000 subcategories were proposed.

For a user who has a very specific area of interest, these categoriesare less than useful at times. For instance, a category that is usefulto a particular user may be either too specific to belong to a generaltaxonomy or will make navigation difficult for the user, as the usermight have to navigate through much of a taxonomy tree. As an example,the category “Think Pad Model 600” is a very specific category which isnot part of a general taxonomy. One other problem of generalizedtaxonomy trees is the fact that these trees are ever growing andconstantly need pruning. Consequently, new categories are added in time,and old categories are deleted. Users are expected to keep up with thechanging taxonomy trees as they perform their searches. Yet anotherproblem is that not all users are familiar with the categorizationscheme. It takes an effort on behalf of the users to navigate throughthe taxonomy tree and find the information searched for within thatcategory. This can cause, among other problems, a lack of returnedinformation.

Metasearch systems help to alleviate the problem of insufficientreturned information. A metasearch system is not a search engine but asystem that merges results from a multitude of search engines. Thus, inthe case of metasearch systems, a query is sent to a multitude ofinformation sources and the results are grouped and merged. While ametasearch system retrieves more information, at the same time, theamount of returned information can be overwhelming.

Therefore, a need still exists for allowing users to search through amassive amount of information, yet provide users with more meaningfulresults than currently presented to the user when searching forinformation.

SUMMARY OF THE INVENTION

Aspects of the present invention improve upon conventional informationsearch techniques by automatically selecting information sources thatare most relevant to user queries. This is done by analyzing results ofsearches returned by information sources for queries and by ranking theinformation sources based on this analysis. The information sources thathave high rankings for a query are subsequently used to search forrelevant results for that query. In other words, information sources canbe selected based on their rankings for a particular query. This processcan be adaptive, as the returned results of old queries can be analyzedat a later date to update the ranking of the information sources,automatic searches can be performed to update the ranking of theinformation sources, new queries can be used for analysis and stored,new information sources added, and old information sources deleted.

Additionally, aspects of the present invention use an electroniclibrary, referred to as a “linguistic library” herein, that is usefulfor storing personal categories for one or more users. Each personalcategory is associated with corresponding keywords and ranked lists ofinformation sources. The personal categories help to expand a user queryand to relate a user query to the ranked information sources. Thelibrary can also contain general categories, taxonomies, anddictionaries used to help broaden and interpret user queries. A user caninteract with the linguistic library to select an appropriate modifiedquery that is based on his or her original query and includesinformation determined from the linguistic library. Alternatively, theuser can submit his or her original query.

A more complete understanding of the present invention, as well asfurther features and advantages of the present invention, will beobtained by reference to the following detailed description anddrawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of an exemplary personalized and adaptivesearch service, in accordance with one embodiment of the presentinvention;

FIG. 2 is a block diagram of an exemplary personal query managerinteracting with a linguistic library and a user, in accordance with oneembodiment of the present invention;

FIG. 3 is a block diagram of an exemplary table of personal categories,in accordance with one embodiment of the present invention;

FIG. 4 is an exemplary method performed by an information sourceanalyzer for determining keyword scores that are then used to rankinformation sources, in accordance with one embodiment of the presentinvention;

FIG. 5 is a representation of how information sources are scored andranked by the information source analyzer, in accordance with oneembodiment of the present invention;

FIG. 6 is an exemplary chart used to illustrate the source ranking shownin FIG. 5; and

FIG. 7 is an exemplary computer system suitable for implementing apersonalized and adaptive search service, in accordance with oneembodiment of the present invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

The present invention allows a user query to be categorized into anumber of categories, where each category is associated with a rankedlist of information sources. The categories effectively allow a userquery to be “expanded” into a number of keywords that can be used asquery terms. The categories also allow a user to navigate informationinstead of or in addition to writing his or her own user query. Thecategories, in one aspect of the invention, also contain a ranked listof information sources. To rank the information sources, a query thatcomprises a number of keywords is sent to each information source. Theset of returned results from an information source is used to determinea ranking. The ranking is then used to search specific informationsources with a user query that corresponds to the category. Generally, aspecific user query is sent to only the highest ranking informationsources. However, the user has the ability to override this. The resultspresented to the user generally come from a subset of all theinformation sources.

In one embodiment, there are personal and general categories. Thepersonal categories are entered through interaction by the user with alinguistic library, and generally when the user is performing his or hersearches. The general categories are categories that are pre-loaded. Thegeneral categories thus provide a user with an already available sourceof query terms for many queries.

In one embodiment of the invention, new user queries are generated,information sources are queried, and information sources are rankedbased results returned against new user queries. The ranking in thisembodiment is performed “offline,” so that the user experiences no slowdown in functionality. The new user query may be based on a previouslyentered user query, which is given its own personal category or isrelated to a general category. If the user enters a user query that hasno corresponding category, then it is beneficial to associate a categoryto the query. Once a category is associated with the query, then thecorresponding keywords and the ranked list of information sources arealso associated with the query. A linguistic library is used to findassociated categories for queries that are not already categorized.Users may choose to interact with the linguistic library to determinethe personal or general category of a query. The linguistic library mayreturn one or more personal or general categories in order for the queryto be categorized. This is done by using dictionaries specific to thedomain of interest. The user may decide which category is the mostappropriate. Optionally, the user may decide to send his or her originalquery, without any data from the linguistic library. In this situation,in one embodiment of the present invention, the query is treated as ametasearch and results are returned from all information sources.

Ranking the information sources generally takes place offline, asretrieving and ranking documents can take a measurable amount of timeand may interfere with the speed experienced by the user. Additionally,if a user has added keywords to a category or modified a category insome other way, it is beneficial to again query the information sourcesand again determine rankings for the information sources. Furthermore,queries may be generated automatically from the keywords that representa category to determine the rank of an information source. The keywordsare sent to information sources and the returned results are analyzedfor rankings. Each category is associated with a number of keywords, andthe query is determined from the keywords corresponding to the category.Categories may be added, deleted, or modified, and information sourcesmay be added, deleted, or modified.

The present invention overcomes a problem with metasearch systems. Asexplained previously, a metasearch system sends a query to a multitudeof information sources and the results are grouped and merged. Theresults are either arranged based on the original scores of thedocuments or are grouped based on the search engine. If the relevance ofthese information sources and their categories to the query is notknown, the returned results are usually not satisfactory. By ranking theinformation sources, the present invention has the ability to return ahigher percentage of relevant documents to the user in a faster fashion.In other words, embodiments of the present invention can determine thatseveral information sources return more relevant documents. If theseinformation sources are searched first, then the results placed highestin a list of returned documents will generally be more pertinent thanthe results obtained by the metasearch system.

Additionally, the arrangement by original scores, where an “originalscore” is a score an information source gives to a document, is noteffective as it could be. In particular, original scores are based onscoring systems from each of the information sources. As manyinformation sources use different document ranking schemes, thenuniformity of scoring is not guaranteed. For instance, a document givena score of “90” by one information source may be only given a score of“50” by another document source. Moreover, as the information sourcesthemselves are not ranked by a metasearch system, there is generallywasted effort. In particular, if it is known, using the techniques ofthe present invention, that three information sources give excellentresults for a particular query, then sending a query to informationsources other than the three information sources could be consideredwasted effort, as the results from the other sources are likely to beless relevant.

The user generally will be given the ability to control how results areviewed. The results could be viewed on one window by ranked informationsources or by using rankings, provided by each information source, forpages within the returned results from the sources, or could be viewedso that each ranked source is in a separate window. There are additionaloptions known to those skilled in the art.

Turning now to FIG. 1, a personalized and adaptive search service 100 isshown interacting with a variety of information sources 180-1 through180-N (collectively, information sources 180) and interacting with auser 103 through user interface 105. Personalized and adaptive searchservice 100 comprises a personal query manager 110, a query generator120, adapter interface 130, document retriever 140, document analyzer150, information source analyzer 160, linguistic library 170, andpersonal query manager 110. Adapter interface 130 comprises a number ofadapters 135-1 through 135-K (collectively, adapters 135). It should benoted that the blocks that are shown in FIG. 1 are demarcated as suchmerely for exposition. The blocks themselves may be combined or evenfurther divided, through techniques known to those skilled in the art.For instance, the blocks information source analyzer 160 and documentanalyzer 150 may be combined into a single functional equivalent of thetwo blocks.

Information sources 180 are any type of information sources available,such as Internet databases, Internet search engines, or public orprivate databases. Any electronic repository of information that can besearched by sending a query and receiving a response can be aninformation source 180.

User 103 interacts with personalized and adaptive search service 100through user interface 105. User interface 105 can comprise a monitor,keyboard, mouse, and other devices suitable for interacting with acomputer system. In this embodiment, the personalized and adaptivesearch service 100 is a computer system or perhaps a server that theuser interface 105 interacts with through a networked computer or a dumbterminal. Additionally, the user interface 105 may comprise a hand-heldcomputer, Personal Digital Assistant (PDA), or cellular phone thataccess the personalized and adaptive search service 100 through a radiofrequency network interface or hardwired network interface.Additionally, personalized and adaptive search service 100 may reside ina PDA or the like. User interface 105 can comprise any device suitablefor communicating information from a user to a computer system.

In one embodiment of the present invention, there are two basic modes ofoperation for personalized and adaptive search service 100: an “online”mode and an “offline” mode. In the online mode, a user 103 createsrequests 106 and receives results 143 through the user interface 105. Inthis mode, the requests 106 can be expanded by the linguistic library170 to include additional keywords and search terms (not shown) andinclude a ranked list (not shown) of information sources 180 to use. Theranked list can include rankings of all of the information sources 180or optionally only a number of the highest ranking information sources180. The number of highest ranking information sources 180 can be userselectable. Additionally, the ranked list can be passed to personalquery manager 110, which can then determine, through user preferences orother criteria, how many of the information sources 180 are selected.Generally, this selection will be done on ranking, so that a number ofhighest ranking information sources 180 are used, but other criteria,such as Internet download speeds, could be used. Moreover, the user 103can enter in a request 106 and the personal query manager 110 can, byaccessing linguistic library 170, determine an expanded query 171 basedon information in the linguistic library 170. This expanded query isshown to the user through feedback 107. The user can accept thisexpanded query, modify it, or use the original query. Thus, feedback 107provides an opportunity for the user to interact with the personal querymanager 110 and linguistic library 170.

In the offline mode, the personalized and adaptive search service 100will communicate a number of queries to the information sources 180 andwill then rank the information sources 180. The queries sent to theinformation sources 180 are the keywords associated with differentcategories stored in linguistic library 170. This way, a ranked list ofrelevant information sources 180 is obtained for each category. Thisoffline mode can be adaptive, as the linguistic library 170 canautomatically send keywords corresponding to categories to the personalquery manager 110, which then provides queries, through personalized andadaptive search service 100, to information sources 180. The returnedresults from searches on the information sources 180 can then be rankedand the rankings stored in linguistic library 170.

In the present specification, it will be assumed that personalized andadaptive search service 100 has both offline and online modes, althoughit should be understood that these modes can be combined into a singlemode where information sources are ranked with each query of one or moreinformation sources 180.

In the online mode, the user 103 sends a user request 106, through userinterface 105, to the personal query manager 110. The user request 106contains a description of a category or topic that the user isinterested in, a user query, or both. Descriptions of categories and thecategories themselves are stored in linguistic library 170, which isdescribed below in more detail in reference to FIGS. 2 and 3. Generally,the user 103 will be using a Graphical User Interface (GUI) in the userinterface 105, which will allow the user 103 to type in a user query ora description of a category, or select a category. Categories are usedto determine the context of a query. For instance, if a user query, inrequest 106, is “java,” it is sent to the linguistic library 170 forfurther analysis. The linguistic library 170 may have multiplecategories associated with the query “java,” such as “computerlanguage,” “islands of Indonesia,” “types of coffee.” If the user haspreviously used this query within the context of “computer language,”then only “computer languages” is returned as the category. Otherwise,the user is asked to select from multiple categories and his selectionis stored in his personal profile in 170.

The personal query manager 110 takes the request 106 and generates amodified query 111 from input from the linguistic library 170. Thelinguistic library 170 uses the request 106 and, through techniquesdescribed in more detail in reference to FIG. 2, expands the request 106into an expanded query 171. Modified and expanded queries are discussedin more detail below.

If the request 106 is already associated with one of the personal orgeneral categories that are stored in the linguistic library 170, thenthe query generator 120 sends a query to a certain number of informationsources 180. Generally, only a number of the highest ranking informationsources 180 are used to perform the search. However, it is possible tosend the query to all of the information sources 180 and then use theranking for each of the information sources 180 to determine whichresults are displayed or the order in which results are displayed. Thedocument retriever 140 retrieves the results, performs any formatting orother modifications, and sends the formatted results 143 back to theuser 103 through user interface 105.

In order to retrieve relevant results, a user query is associated with acategory. If there is a match between a user query and a category, thenthe keywords associated with the category are used to search. If thereis no match, then the user interacts with the linguistic library 170 todetermine an appropriate category. The details of generating query termsspecific to a user category are discussed in reference to FIG. 2. If anappropriate category, either a user category or a general category, doesnot exist, then the personalized and adaptive search service 100 actslike a metasearch device, in that personalized and adaptive searchservice 100 sends the user query to each of the information sources 180and returns the results to the user 103 through returned results 143.Additionally, the user may choose to not interact with informationsources 180 or may choose to have the personalized and adaptive searchservice 100 act as a metasearch device, regardless of whether or not anappropriate category can be found.

In offline mode, personalized and adaptive search service 100 operatesas follows. The personal query manager 110 will send a number of queriesto the information sources 180. Each query generally comprises, as shownmore particularly in FIG. 3, one or more keywords. A query is sent tothe query generator 120, which performs formatting specific to each ofthe information sources 180. Some information sources 180 may allowcharacter strings to be sent to them as queries; other may require aspecific format. The query generator 120 performs any needed formatting.Thus, the query generator 120 might create several different finalqueries 121, which are then directed to the appropriate informationsources 180.

Adapters 130 is a central location used to store a number of adapters135. Each adapter 135 is adapted to interact with one or moreinformation sources 180. Each adapter 135 performs low levelcommunication with an information source 180. For example, the adapter135-1 could be an adapter for use with a database on the Internet, andthe adapter 135-1 would open and close communications with theinformation source 180 using protocols specific to the informationsource 180. Usually, there will be fewer adapters 135 than informationsources 180, as many information sources 180 will use the sameprotocols. In the example of FIG. 1, there are K adapters 130 and Ninformation sources 180, where K<N. Additionally, there could be anadapter 135 that exists but no information source 180 that correspondsto it.

Each final query 121 is transmitted, through adapters 135 to the Ninformation sources 180. Each information source 180 returns results136. The document retriever 140 keeps track of the results. Inparticular, the document retriever 140 catalogs results from each of theinformation sources 180. The cataloging by the document retriever 140includes, in one embodiment, for each document, a title and a UniformResource Locator (URL). Any technique for allowing a system to accessthe document may be used by the document retriever 140. Additionally,the number of documents returned by each information sources 180 isretained. This information is sent to the document analyzer 150 asreturned results 141. These returned results may be stored for lateranalysis, which is used to update the rankings of the informationsources. In online mode, this information is also sent to the user asreturned results 143.

Generally, the returned results 141, 143 will be a list of HyperTextTransfer Protocol (HTTP) addresses, possibly along with titles, briefdescriptions, and other information. For instance, an exemplary list ofthree entries in a returned result 141, 143 for the query “java andprogram and language” could be the following:

1. “Language Basics.”http://java.sun.com/docs/books/tutorial/java/nutsandbolts/

2. “Essentials of the Java™ Programming Language, Part 1,”http://developer.java.sun.com/developer/onlineTraining/Programming/BasicJava1/

3. “Java—Webopedia.com,” http://www.webopedia.com/TERM/J/Java.htm

In the above returned results, the titles are “Language Basics,”“Essentials of the Java™ Programming Language, Part 1,” and“Java—Webopedia.com.” The HTTP addresses corresponding to these titlesfollow the titles. Document retriever 140 will generally send completeentries in the returned results 143 to the user 103. In other words, theentire entry, including title, HTTP address, and any other information,will be sent.

It is also possible for the returned results 141, 143 to include thedocuments themselves, instead of HTTP addresses. It should also be notedthat the returned results 141, 143 can include scores created by theinformation sources 180.

The document analyzer 150 analyzes the documents by determining a scorefor each document. The query is used to determine the score for adocument. The score is determined through techniques known to thoseskilled in the art. Such techniques are described in Selberg, “TowardsComprehensive Web Search,” Ph.D. Dissertation, University of Washington(1999); Howe and Dreilinger, “Savvy-Search: A Meta-Search Engine thatLearns which Search Engine to Query,” AI Magazine, 18(2) (1997);Lawrence and Giles, “Inquirus, the NECI meta search engine,” SeventhIntl World Wide Web Conference, Australia, 95-105 (1998), thedisclosures of which are hereby incorporated by reference. By using asingle technique to score documents for each of the information sources180, there is uniformity of scoring for each of the information sources180. For instance, it is possible to use scores from the informationsources 180 themselves to perform the scoring. However, the techniquesused to score documents for each information source 180 will likelydiffer, and some information sources 180 may not use any scoringmechanisms. Thus, using the same technique to score each documentprovides uniform scoring. It should be noted that two or more techniquesmay be used to score documents, and scores from each technique can becombined, such as through an average. However, each technique can take ameasurable and sometimes substantial amount of time. Consequently, usingonly one technique is suitable for most applications.

The document analyzer 150 sends data 151 about an information source toinformation source analyzer 160. The data 151 comprises a list ofdocument scores and a total number of returned documents for eachinformation source 180. Information source analyzer 160 analyzes thescores and total number of returned documents and ranks sources.Exemplary analysis techniques are described below in more detail inreference to FIGS. 4 through 6. The information source analyzer 160sends the ranked list 161 of information sources 180 to the linguisticlibrary 170, along with the associated query and category. When thelinguistic library 170 receives the ranked list of information sources180 through link 161, the linguistic library 170 updates the categorywith the ranked list 161 of information sources 180, as described belowin reference to FIG. 3.

Thus, in offline mode, the personalized and adaptive search service 100ranks information sources 180 so that future requests 106 by a user willbe transmitted, in online mode, to more appropriate information sources180. The personalized and adaptive search service 100 identifies themost relevant information sources 180 for most, if not all, requests 106by a user.

Although reference numerals 106, 107, 111, 112, 121, 136, 141, 151, 161,and 171 have been primarily described by the data passing through these“links,” it is not necessary to have any type of hardware implementationfor these links. For instance, link 161 simply indicates that data ispassed between modules. The actual link 161 could simply be a referenceto an object or memory location, as is known in the art. Any mechanismsuitable for passing data may be used as a link. Moreover, multipletypes of data can pass through any link.

It should be noted that personalized and adaptive search service 100could be implemented as a “plug in” to a browser or similar software. Inthis configuration, the personalized and adaptive search service 100would operate largely at a remote site out of sight for most users.

Before turning to FIG. 2, it is worthwhile to provide an example. If auser enters the request 106 of “java,” then, as discussed above, thepersonal query manager 110 will access the linguistic library 170 todetermine if there are any suitable categories for this request 106. Theuser 103 can then be presented with categories such as “computerlanguage,” “islands of Indonesia,” and “types of coffee.” If the user103 select “computer language,” the fact that the user selected thiscategory and not another category may be stored in linguistic library170, particularly in the user profile/preferences (described below).Once the user selects a category, the linguistic library 170 willprovide keywords associated with that category. Alternatively, thekeywords could be provided at the same time as the categories areprovided. The keywords could include, for example, lava, “program,”“language,” and “computer.”

These keywords are sent to personal query manager 110, which allows theuser 103 to modify or add to these keywords, if desired. It will beassumed, for sake of simplicity, that the user 103 does not modify thekeywords. The keywords are sent to the query generator 120, which thenformats one final query 121 as “java program language computer,” wherethe boolean operation “and” or “or” is assumed to occur between words.Another final query 121 may be formatted by query generator 120 as “javaand program and language and computer.” Each of these final queries 121is directed to an appropriate adapter 135, which then directs the finalquery to one or more information sources 180. Results 136 are returnedto document retriever 140, which collects the results 136, organizesthem by source (if desired), and sends them to user 143.

If the user decides to not select a category and just sends the request106 as “java,” then this query is passed through the personal querymanager 110, to the query generator 120, which performs any neededformatting, through the adapters 135 and to the information sources 180.Results 136 are passed through document retriever 140, which collectsand organizes the results per information sources 180 and then sends theorganized result list on link 143.

During offline mode, the linguistic library 170 will pass keywords foreach of the categories “computer language,” “islands of Indonesia,” and“types of coffee” to the personal query manager 110, which will forwardeach set of keywords to query generator 120, which then formats eachquery appropriately for the adapters 135. The adapters 135 send thequeries to the appropriate information sources 180, which return results136. The document retriever 140 determines how many results are returnedfor each information sources 180 and catalogs the results. This data issent through link 141 to document analyzer 150, which analyzes thedocuments and scores the relevancy of the documents. The total number ofreturned documents for each information sources 180 and scores are sentto information source analyzer 160, which determines rankings of theinformation sources 180 for each of the queries.

Referring now to FIG. 2, a portion of FIG. 1 is shown in greater detail.Personal query manager 110 comprises a request handler 210, a searchutility 220, and a query interface generator 215. The linguistic library170 comprises one or more tables of general categories 235, userspecific taxonomies 240, table of personal categories 245, anddictionaries 250.

A user request 106, which could be a user category description,category, or query, is sent to request handler 210. The request 106 isreceived by the request handler 210, which parses the user descriptionand sends the parsed terms to the linguistic resources library 170 viasearch utility 220 and link 112. The search utility 220 finds therelated terms and categories associated with the description or query inthe request 106 as well as the most relevant information sources 180that should be searched against the request 106. Additionally, thesearch utility 220 can find personal preferences stored in userprofile/preferences 255. A search of the general categories 235 yieldscategories that have the same keywords or description as the userrequest 106. User specific taxonomies 240 are classifications specificto the user. A search of these will yield classifications used tobroaden the request 106. A dictionary 250 provides definitions that maybe used to broaden the request 106 or used to associate categories withthe user request 106. It should be noted that a dictionary can containthesaurus information. A table suitable for general categories 235 andpersonal categories 245 is shown in FIG. 3.

If the search by the search utility 220 returns at least one categoryand associated information sources 180, then this information is used toretrieve relevant documents. The linguistic library 170 generates termsrelated to the request 106 and returns the terms back to the personalquery manager 110 through link 171. An expanded query is created bysearch utility 220 and linguistic library 170 and terms for the expandedquery, or the expanded query itself, are passed through link 171 andshown to the user through link 107. At this point, user 105 may chooseto modify these terms before they are submitted to the query generator120. The final version of the keywords and query terms 115 are thensubmitted to the query generator 120, through query generator interface215, where the adapters 170 are invoked to submit multiple searchrequests to various information sources 180 simultaneously. The querygenerator interface 215 sends keywords, or other terms determined fromlinguistic library 170, to the query generator 120.

Referring now to FIG. 3, an exemplary table of categories 300 is shown.The table of categories 300 may be the table of general categories 235or the table of personal categories 245. As noted above, thepersonalized and adaptive search service 100 generally will come with anumber of categories in the table of general categories 235, and theuser (or users) can add his or her own additional categories in thetable of personal categories 245. FIG. 3 shows the structure of a tableto be used to store and retrieve categories and associated keywords andinformation sources. In table of categories 300, the first column 305 isfor the textual description of the user category, the second column 310is for the array of keywords that are associated with the categorydescription, and the last column 315 is for the list of informationsources that are sorted based on their rank and related to the categorydescribed in the first column. Category 320 corresponds to L keywords325 and ranked list 330; category 335 corresponds to M keywords 340 andranked list 345; and category 350 corresponds to P keywords 355 andranked list 360. In the example of FIG. 3, there are Z categories.

The user queries and descriptions are first checked against the table ofpersonal categories 245 and the table of general categories 235. Ifthere exists a category, in either of these tables, that is found whencompared to a user query or description, then associated informationsources in a corresponding ranked list 315 are used to retrieveinformation. Otherwise, a new category is created in the table ofpersonal categories 245 by querying the user as to the textualdescription of the category and populating another row in the table. Thekeywords 310 for the new row in the table of personal categories 245come from the table of general categories 235 and dictionary 250. Thedictionary is used to determine words related to the newly added textualdescription of the category. These words are then used to determinesimilar categories in the table of general categories 235, and thekeywords for the similar categories from table of general categories 235are added to the table of personal categories 245 as keywords. The newlyadded keywords are generally shown to the user, who can then determineto add, delete, or modify the keywords.

In the example of FIG. 3, each ranked list 315 of information sources180 is in order of information source and not ranking. However, the listmay be placed in order of ranking if desired. One benefit to having theranked lists 315 ordered in order of information source is that it iseasier to remove or add sources.

There are multiple ways of ranking information sources 180. One possibleway of ranking the information sources 180 is based on the number ofdocuments returned from each information source 180. The informationsource 180 that returns more documents is ranked higher than otherinformation sources 180 that return less number of documents. As anexample, source A that returns 100 documents on one subject is rankedhigher than source B that returns 50.

However, the relevance of the returned documents is important. Anotherranking policy that takes relevancy into consideration works as is shownin FIG. 4. Broadly, each document is assigned a relevance score by thesource. During the ranking process of method 400, a keyword score for aparticular keyword can be calculated based on a formula which definesthe keyword score as the linear combination of the number of documentsand their mean relevancy. Method 400 determines a keyword score for eachkeyword and should be run once for each keyword and information source180.

Method 400 begins in step 405, when an index and a total score are setto zero. In step 410, the index is incremented. In step 415, a score ofthe current document is determined. This score is determined for aparticular keyword or query. Generally, the information source analyzer160 performs method 400 and will simply retrieve the score for thedocument. In other words, the score has already been determined by thedocument analyzer 150 for the keyword and the information sourceanalyzer 160 just retrieves the score. Alternatively, it is possible tohave the document analyzer 150 determine the score in step 415 and havethe document analyzer 150 provide the score to information sourceanalyzer 160. It is also possible to have the information sourceanalyzer 160 determine the score, if desired.

In step 420, the current score for the keyword is added to the totaldocument score. In step 425, it is determined if there are moredocuments. If there are more documents, the method 400 continues in step410, otherwise step 430 is performed. The loop of steps 410 through 425will create a total document score that is a linear addition of all ofthe scores for documents that contain a keyword and that are from asingle source.

In step 430, an average document score is created for the informationsource by dividing the total score by the number of documents returned.A measure of quality is determined in step 435 using the followingformula:

a*average document score,

where “a” is a constant. A measure of quantity is determined in step 440by using the following formula:

b*number of documents returned,

where “b” is another constant. The constants a and b are to bedetermined depending on the importance of quality or the quantity. Ifthe quality (i.e., relevance) is not important, then b=0; on the otherhand, if the quantity (i.e., number of documents) is not important, thena=0. The values of a and b can be determined by users as part of theirprofile. Here, it is assumed that the document scores retrieved fromdifferent sources are normalized. In step 445, a keyword score isdetermined by the following equation:

$\begin{matrix}{{{{Keyword}\mspace{14mu} {Score}} = {\left( {{Measure}\mspace{14mu} {of}\mspace{14mu} {Quality}} \right) + \left( {{Measure}\mspace{14mu} {of}\mspace{14mu} {Quantity}} \right)}},{or}} \\{= {{a*{average}\mspace{14mu} {document}\mspace{14mu} {score}} +}} \\{{b*{number}\mspace{14mu} {of}\mspace{14mu} {documents}\mspace{14mu} {returned}}}\end{matrix}$

FIG. 5 shows a representation of how information sources are scored andranked. The information source A is scored based on all the keywordsthat represent the category of choice. In this example, there are fourkeywords, keyword, through keyword₄, for the category being examined.The scores of source A are 50, 76, 55 and 20, for the four keywords,respectively. Each score is determined through method 400. Hence, thetotal score of source A is 201, which is a simple addition of each ofthe keyword scores, that ranks this source as the 3rd after source B andD. The rank is determined from the source scores; the higher the score,the lower the rank in this example (i.e., lower scores are better).

More complex analyses may be used in the techniques described in FIG. 5.For instance, weighting may be applied to the scores of each keyword,such that one keyword could be weighted higher than another. Anytechnique for determining an overall score for a query having keywordsmay be used.

FIG. 6 shows a representation of scoring of the sources. It should benoted that the scores themselves may be used as the ranking of theinformation sources.

Turning now to FIG. 7, a block diagram is shown of a computer system 700for performing the methods and techniques of a personalized and adaptivesearch service 100 in accordance with one embodiment of the presentinvention. Computer system 700 is shown interacting with a DigitalVersatile Disk (DVD) 760 and a computer network. Computer system 700comprises a processor 710, a memory 720, a network interface 730, amedia interface 740 and a peripheral interface 750. Network interface730 allows computer system 700 to connect to a network, while mediainterface 740 allows computer system 700 to interact with media such asa hard drive or DVD 760. Peripheral interface 750 is an interface thatinteracts with monitors, mice, keyboards, and other devices to enablehuman interaction with computer system 700.

As is known in the art, the methods and apparatus discussed herein maybe distributed as an article of manufacture that itself comprises acomputer-readable medium having computer-readable code means embodiedthereon. The computer-readable program code means is operable, inconjunction with a computer system such as computer system 700, to carryout all or some of the steps to perform the methods or create theapparatuses discussed herein. The computer-readable medium may be arecordable medium (e.g., floppy disks, hard drives, optical disks suchas DVD 760, or memory cards) or may be a transmission medium (e.g., anetwork comprising fiber-optics, the world-wide web, cables, or awireless channel using time-division multiple access, code-divisionmultiple access, or other radio-frequency channel). Any medium known ordeveloped that can store information suitable for use with a computersystem may be used. The computer-readable code means is any mechanismfor allowing a computer to read instructions and data, such as magneticvariations on a magnetic medium or height variations on the surface of acompact disk, such as DVD 760.

Memory 720 configures the processor 710 to implement the methods, steps,and functions disclosed herein. The memory 720 could be distributed orlocal and the processor 710 could be distributed or singular. The memory720 could be implemented as an electrical, magnetic or optical memory,or any combination of these or other types of storage devices. Moreover,the term “memory” should be construed broadly enough to encompass anyinformation able to be read from or written to an address in theaddressable space accessed by processor 710. With this definition,information on a network, accessible through network interface 730, isstill within memory 720 because the processor 710 can retrieve theinformation from the network. It should be noted that each distributedprocessor that makes up processor 710 generally contains its ownaddressable memory space. It should also be noted that some or all ofcomputer system 700 can be incorporated into an application-specific orgeneral-use integrated circuit.

It is to be understood that the embodiments and variations shown anddescribed herein are merely illustrative of the principles of thisinvention and that various modifications may be implemented by thoseskilled in the art without departing from the scope and spirit of theinvention.

1. A computer-implemented method, comprising: defining one or morepersonalized categories, wherein each personalized category comprisesone or more terms; identifying one or more of said personalizedcategories that are associated with a user query; identifying one ormore terms that are associated with said user query and with saidpersonalized category; and adding said identified one or more terms tosaid user query.
 2. The method of claim 1, wherein a user enters theuser query.
 3. The method of claim 1, further comprising: storing theuser query.
 4. The method of claim 3, wherein storing the user queryfurther comprises storing a plurality of user queries.
 5. The method ofclaim 1, further comprising: selecting a query.
 6. An apparatuscomprising: one ore more memories that store computer-readable code; andone or more processors operatively coupled to the one or more memories,the one or more processors configured to implement the computer-readablecode, the computer-readable code configured to: define one or morepersonalized categories, wherein each personalized category comprisesone or more terms; identify one or more of said personalized categoriesthat are associated with a user query; identify one or more terms thatare associated with said user query and with said personalized category;and add said identified one or more terms to said user query.
 7. Theapparatus of claim 6, wherein a user enters the user query.
 8. Theapparatus of claim 6, wherein the computer-readable code is furtherconfigured to: store the user query.
 9. The apparatus of claim 8,wherein storing the user query further comprises storing a plurality ofuser queries.
 10. The apparatus of claim 6, wherein thecomputer-readable code is further configured to: select a query.